// Copyright 2008, Google Inc.
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
//     * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
//     * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
//     * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
//
// This file tests the internal cross-platform support utilities.
#include <stdio.h>

#include "gtest/internal/gtest-port.h"

#if GTEST_OS_MAC
#include <time.h>
#endif // GTEST_OS_MAC

#include <list>
#include <utility> // For std::pair and std::make_pair.
#include <vector>

#include "gtest/gtest.h"
#include "gtest/gtest-spi.h"
#include "src/gtest-internal-inl.h"

using std::make_pair;
using std::pair;

namespace testing {
namespace internal {

TEST(IsXDigitTest, WorksForNarrowAscii)
{
    EXPECT_TRUE(IsXDigit('0'));
    EXPECT_TRUE(IsXDigit('9'));
    EXPECT_TRUE(IsXDigit('A'));
    EXPECT_TRUE(IsXDigit('F'));
    EXPECT_TRUE(IsXDigit('a'));
    EXPECT_TRUE(IsXDigit('f'));

    EXPECT_FALSE(IsXDigit('-'));
    EXPECT_FALSE(IsXDigit('g'));
    EXPECT_FALSE(IsXDigit('G'));
}

TEST(IsXDigitTest, ReturnsFalseForNarrowNonAscii)
{
    EXPECT_FALSE(IsXDigit(static_cast<char>('\x80')));
    EXPECT_FALSE(IsXDigit(static_cast<char>('0' | '\x80')));
}

TEST(IsXDigitTest, WorksForWideAscii)
{
    EXPECT_TRUE(IsXDigit(L'0'));
    EXPECT_TRUE(IsXDigit(L'9'));
    EXPECT_TRUE(IsXDigit(L'A'));
    EXPECT_TRUE(IsXDigit(L'F'));
    EXPECT_TRUE(IsXDigit(L'a'));
    EXPECT_TRUE(IsXDigit(L'f'));

    EXPECT_FALSE(IsXDigit(L'-'));
    EXPECT_FALSE(IsXDigit(L'g'));
    EXPECT_FALSE(IsXDigit(L'G'));
}

TEST(IsXDigitTest, ReturnsFalseForWideNonAscii)
{
    EXPECT_FALSE(IsXDigit(static_cast<wchar_t>(0x80)));
    EXPECT_FALSE(IsXDigit(static_cast<wchar_t>(L'0' | 0x80)));
    EXPECT_FALSE(IsXDigit(static_cast<wchar_t>(L'0' | 0x100)));
}

class Base
{
public:
    // Copy constructor and assignment operator do exactly what we need, so we
    // use them.
    Base()
        : member_(0)
    {
    }
    explicit Base(int n)
        : member_(n)
    {
    }
    virtual ~Base() {}
    int member() { return member_; }

private:
    int member_;
};

class Derived : public Base
{
public:
    explicit Derived(int n)
        : Base(n)
    {
    }
};

TEST(ImplicitCastTest, ConvertsPointers)
{
    Derived derived(0);
    EXPECT_TRUE(&derived == ::testing::internal::ImplicitCast_<Base *>(&derived));
}

TEST(ImplicitCastTest, CanUseInheritance)
{
    Derived derived(1);
    Base base = ::testing::internal::ImplicitCast_<Base>(derived);
    EXPECT_EQ(derived.member(), base.member());
}

class Castable
{
public:
    explicit Castable(bool *converted)
        : converted_(converted)
    {
    }
    operator Base()
    {
        *converted_ = true;
        return Base();
    }

private:
    bool *converted_;
};

TEST(ImplicitCastTest, CanUseNonConstCastOperator)
{
    bool converted = false;
    Castable castable(&converted);
    Base base = ::testing::internal::ImplicitCast_<Base>(castable);
    EXPECT_TRUE(converted);
}

class ConstCastable
{
public:
    explicit ConstCastable(bool *converted)
        : converted_(converted)
    {
    }
    operator Base() const
    {
        *converted_ = true;
        return Base();
    }

private:
    bool *converted_;
};

TEST(ImplicitCastTest, CanUseConstCastOperatorOnConstValues)
{
    bool converted = false;
    const ConstCastable const_castable(&converted);
    Base base = ::testing::internal::ImplicitCast_<Base>(const_castable);
    EXPECT_TRUE(converted);
}

class ConstAndNonConstCastable
{
public:
    ConstAndNonConstCastable(bool *converted, bool *const_converted)
        : converted_(converted)
        , const_converted_(const_converted)
    {
    }
    operator Base()
    {
        *converted_ = true;
        return Base();
    }
    operator Base() const
    {
        *const_converted_ = true;
        return Base();
    }

private:
    bool *converted_;
    bool *const_converted_;
};

TEST(ImplicitCastTest, CanSelectBetweenConstAndNonConstCasrAppropriately)
{
    bool converted = false;
    bool const_converted = false;
    ConstAndNonConstCastable castable(&converted, &const_converted);
    Base base = ::testing::internal::ImplicitCast_<Base>(castable);
    EXPECT_TRUE(converted);
    EXPECT_FALSE(const_converted);

    converted = false;
    const_converted = false;
    const ConstAndNonConstCastable const_castable(&converted, &const_converted);
    base = ::testing::internal::ImplicitCast_<Base>(const_castable);
    EXPECT_FALSE(converted);
    EXPECT_TRUE(const_converted);
}

class To
{
public:
    To(bool *converted) { *converted = true; } // NOLINT
};

TEST(ImplicitCastTest, CanUseImplicitConstructor)
{
    bool converted = false;
    To to = ::testing::internal::ImplicitCast_<To>(&converted);
    (void)to;
    EXPECT_TRUE(converted);
}

TEST(IteratorTraitsTest, WorksForSTLContainerIterators)
{
    StaticAssertTypeEq<int,
                       IteratorTraits<::std::vector<int>::const_iterator>::value_type>();
    StaticAssertTypeEq<bool,
                       IteratorTraits<::std::list<bool>::iterator>::value_type>();
}

TEST(IteratorTraitsTest, WorksForPointerToNonConst)
{
    StaticAssertTypeEq<char, IteratorTraits<char *>::value_type>();
    StaticAssertTypeEq<const void *, IteratorTraits<const void **>::value_type>();
}

TEST(IteratorTraitsTest, WorksForPointerToConst)
{
    StaticAssertTypeEq<char, IteratorTraits<const char *>::value_type>();
    StaticAssertTypeEq<const void *,
                       IteratorTraits<const void *const *>::value_type>();
}

// Tests that the element_type typedef is available in scoped_ptr and refers
// to the parameter type.
TEST(ScopedPtrTest, DefinesElementType)
{
    StaticAssertTypeEq<int, ::testing::internal::scoped_ptr<int>::element_type>();
}

// FIXME: Implement THE REST of scoped_ptr tests.

TEST(GtestCheckSyntaxTest, BehavesLikeASingleStatement)
{
    if (AlwaysFalse())
        GTEST_CHECK_(false) << "This should never be executed; "
                               "It's a compilation test only.";

    if (AlwaysTrue())
        GTEST_CHECK_(true);
    else
        ; // NOLINT

    if (AlwaysFalse())
        ; // NOLINT
    else
        GTEST_CHECK_(true) << "";
}

TEST(GtestCheckSyntaxTest, WorksWithSwitch)
{
    switch (0) {
    case 1:
        break;
    default:
        GTEST_CHECK_(true);
    }

    switch (0)
    case 0:
        GTEST_CHECK_(true) << "Check failed in switch case";
}

// Verifies behavior of FormatFileLocation.
TEST(FormatFileLocationTest, FormatsFileLocation)
{
    EXPECT_PRED_FORMAT2(IsSubstring, "foo.cc", FormatFileLocation("foo.cc", 42));
    EXPECT_PRED_FORMAT2(IsSubstring, "42", FormatFileLocation("foo.cc", 42));
}

TEST(FormatFileLocationTest, FormatsUnknownFile)
{
    EXPECT_PRED_FORMAT2(
        IsSubstring, "unknown file", FormatFileLocation(NULL, 42));
    EXPECT_PRED_FORMAT2(IsSubstring, "42", FormatFileLocation(NULL, 42));
}

TEST(FormatFileLocationTest, FormatsUknownLine)
{
    EXPECT_EQ("foo.cc:", FormatFileLocation("foo.cc", -1));
}

TEST(FormatFileLocationTest, FormatsUknownFileAndLine)
{
    EXPECT_EQ("unknown file:", FormatFileLocation(NULL, -1));
}

// Verifies behavior of FormatCompilerIndependentFileLocation.
TEST(FormatCompilerIndependentFileLocationTest, FormatsFileLocation)
{
    EXPECT_EQ("foo.cc:42", FormatCompilerIndependentFileLocation("foo.cc", 42));
}

TEST(FormatCompilerIndependentFileLocationTest, FormatsUknownFile)
{
    EXPECT_EQ("unknown file:42",
              FormatCompilerIndependentFileLocation(NULL, 42));
}

TEST(FormatCompilerIndependentFileLocationTest, FormatsUknownLine)
{
    EXPECT_EQ("foo.cc", FormatCompilerIndependentFileLocation("foo.cc", -1));
}

TEST(FormatCompilerIndependentFileLocationTest, FormatsUknownFileAndLine)
{
    EXPECT_EQ("unknown file", FormatCompilerIndependentFileLocation(NULL, -1));
}

#if GTEST_OS_LINUX || GTEST_OS_MAC || GTEST_OS_QNX || GTEST_OS_FUCHSIA
void *ThreadFunc(void *data)
{
    internal::Mutex *mutex = static_cast<internal::Mutex *>(data);
    mutex->Lock();
    mutex->Unlock();
    return NULL;
}

TEST(GetThreadCountTest, ReturnsCorrectValue)
{
    const size_t starting_count = GetThreadCount();
    pthread_t thread_id;

    internal::Mutex mutex;
    {
        internal::MutexLock lock(&mutex);
        pthread_attr_t attr;
        ASSERT_EQ(0, pthread_attr_init(&attr));
        ASSERT_EQ(0, pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_JOINABLE));

        const int status = pthread_create(&thread_id, &attr, &ThreadFunc, &mutex);
        ASSERT_EQ(0, pthread_attr_destroy(&attr));
        ASSERT_EQ(0, status);
        EXPECT_EQ(starting_count + 1, GetThreadCount());
    }

    void *dummy;
    ASSERT_EQ(0, pthread_join(thread_id, &dummy));

    // The OS may not immediately report the updated thread count after
    // joining a thread, causing flakiness in this test. To counter that, we
    // wait for up to .5 seconds for the OS to report the correct value.
    for (int i = 0; i < 5; ++i) {
        if (GetThreadCount() == starting_count)
            break;

        SleepMilliseconds(100);
    }

    EXPECT_EQ(starting_count, GetThreadCount());
}
#else
TEST(GetThreadCountTest, ReturnsZeroWhenUnableToCountThreads)
{
    EXPECT_EQ(0U, GetThreadCount());
}
#endif // GTEST_OS_LINUX || GTEST_OS_MAC || GTEST_OS_QNX || GTEST_OS_FUCHSIA

TEST(GtestCheckDeathTest, DiesWithCorrectOutputOnFailure)
{
    const bool a_false_condition = false;
    const char regex[] =
#ifdef _MSC_VER
        "googletest-port-test\\.cc\\(\\d+\\):"
#elif GTEST_USES_POSIX_RE
        "googletest-port-test\\.cc:[0-9]+"
#else
        "googletest-port-test\\.cc:\\d+"
#endif // _MSC_VER
        ".*a_false_condition.*Extra info.*";

    EXPECT_DEATH_IF_SUPPORTED(GTEST_CHECK_(a_false_condition) << "Extra info",
                              regex);
}

#if GTEST_HAS_DEATH_TEST

TEST(GtestCheckDeathTest, LivesSilentlyOnSuccess)
{
    EXPECT_EXIT({
      GTEST_CHECK_(true) << "Extra info";
      ::std::cerr << "Success\n";
      exit(0); },
                ::testing::ExitedWithCode(0), "Success");
}

#endif // GTEST_HAS_DEATH_TEST

// Verifies that Google Test choose regular expression engine appropriate to
// the platform. The test will produce compiler errors in case of failure.
// For simplicity, we only cover the most important platforms here.
TEST(RegexEngineSelectionTest, SelectsCorrectRegexEngine)
{
#if !GTEST_USES_PCRE
#if GTEST_HAS_POSIX_RE

    EXPECT_TRUE(GTEST_USES_POSIX_RE);

#else

    EXPECT_TRUE(GTEST_USES_SIMPLE_RE);

#endif
#endif // !GTEST_USES_PCRE
}

#if GTEST_USES_POSIX_RE

#if GTEST_HAS_TYPED_TEST

template<typename Str>
class RETest : public ::testing::Test
{
};

// Defines StringTypes as the list of all string types that class RE
// supports.
typedef testing::Types<
    ::std::string,
#if GTEST_HAS_GLOBAL_STRING
    ::string,
#endif // GTEST_HAS_GLOBAL_STRING
    const char *>
    StringTypes;

TYPED_TEST_CASE(RETest, StringTypes);

// Tests RE's implicit constructors.
TYPED_TEST(RETest, ImplicitConstructorWorks)
{
    const RE empty(TypeParam(""));
    EXPECT_STREQ("", empty.pattern());

    const RE simple(TypeParam("hello"));
    EXPECT_STREQ("hello", simple.pattern());

    const RE normal(TypeParam(".*(\\w+)"));
    EXPECT_STREQ(".*(\\w+)", normal.pattern());
}

// Tests that RE's constructors reject invalid regular expressions.
TYPED_TEST(RETest, RejectsInvalidRegex)
{
    EXPECT_NONFATAL_FAILURE({
        const RE invalid(TypeParam("?"));
    },
                            "\"?\" is not a valid POSIX Extended regular expression.");
}

// Tests RE::FullMatch().
TYPED_TEST(RETest, FullMatchWorks)
{
    const RE empty(TypeParam(""));
    EXPECT_TRUE(RE::FullMatch(TypeParam(""), empty));
    EXPECT_FALSE(RE::FullMatch(TypeParam("a"), empty));

    const RE re(TypeParam("a.*z"));
    EXPECT_TRUE(RE::FullMatch(TypeParam("az"), re));
    EXPECT_TRUE(RE::FullMatch(TypeParam("axyz"), re));
    EXPECT_FALSE(RE::FullMatch(TypeParam("baz"), re));
    EXPECT_FALSE(RE::FullMatch(TypeParam("azy"), re));
}

// Tests RE::PartialMatch().
TYPED_TEST(RETest, PartialMatchWorks)
{
    const RE empty(TypeParam(""));
    EXPECT_TRUE(RE::PartialMatch(TypeParam(""), empty));
    EXPECT_TRUE(RE::PartialMatch(TypeParam("a"), empty));

    const RE re(TypeParam("a.*z"));
    EXPECT_TRUE(RE::PartialMatch(TypeParam("az"), re));
    EXPECT_TRUE(RE::PartialMatch(TypeParam("axyz"), re));
    EXPECT_TRUE(RE::PartialMatch(TypeParam("baz"), re));
    EXPECT_TRUE(RE::PartialMatch(TypeParam("azy"), re));
    EXPECT_FALSE(RE::PartialMatch(TypeParam("zza"), re));
}

#endif // GTEST_HAS_TYPED_TEST

#elif GTEST_USES_SIMPLE_RE

TEST(IsInSetTest, NulCharIsNotInAnySet)
{
    EXPECT_FALSE(IsInSet('\0', ""));
    EXPECT_FALSE(IsInSet('\0', "\0"));
    EXPECT_FALSE(IsInSet('\0', "a"));
}

TEST(IsInSetTest, WorksForNonNulChars)
{
    EXPECT_FALSE(IsInSet('a', "Ab"));
    EXPECT_FALSE(IsInSet('c', ""));

    EXPECT_TRUE(IsInSet('b', "bcd"));
    EXPECT_TRUE(IsInSet('b', "ab"));
}

TEST(IsAsciiDigitTest, IsFalseForNonDigit)
{
    EXPECT_FALSE(IsAsciiDigit('\0'));
    EXPECT_FALSE(IsAsciiDigit(' '));
    EXPECT_FALSE(IsAsciiDigit('+'));
    EXPECT_FALSE(IsAsciiDigit('-'));
    EXPECT_FALSE(IsAsciiDigit('.'));
    EXPECT_FALSE(IsAsciiDigit('a'));
}

TEST(IsAsciiDigitTest, IsTrueForDigit)
{
    EXPECT_TRUE(IsAsciiDigit('0'));
    EXPECT_TRUE(IsAsciiDigit('1'));
    EXPECT_TRUE(IsAsciiDigit('5'));
    EXPECT_TRUE(IsAsciiDigit('9'));
}

TEST(IsAsciiPunctTest, IsFalseForNonPunct)
{
    EXPECT_FALSE(IsAsciiPunct('\0'));
    EXPECT_FALSE(IsAsciiPunct(' '));
    EXPECT_FALSE(IsAsciiPunct('\n'));
    EXPECT_FALSE(IsAsciiPunct('a'));
    EXPECT_FALSE(IsAsciiPunct('0'));
}

TEST(IsAsciiPunctTest, IsTrueForPunct)
{
    for (const char *p = "^-!\"#$%&'()*+,./:;<=>?@[\\]_`{|}~"; *p; p++) {
        EXPECT_PRED1(IsAsciiPunct, *p);
    }
}

TEST(IsRepeatTest, IsFalseForNonRepeatChar)
{
    EXPECT_FALSE(IsRepeat('\0'));
    EXPECT_FALSE(IsRepeat(' '));
    EXPECT_FALSE(IsRepeat('a'));
    EXPECT_FALSE(IsRepeat('1'));
    EXPECT_FALSE(IsRepeat('-'));
}

TEST(IsRepeatTest, IsTrueForRepeatChar)
{
    EXPECT_TRUE(IsRepeat('?'));
    EXPECT_TRUE(IsRepeat('*'));
    EXPECT_TRUE(IsRepeat('+'));
}

TEST(IsAsciiWhiteSpaceTest, IsFalseForNonWhiteSpace)
{
    EXPECT_FALSE(IsAsciiWhiteSpace('\0'));
    EXPECT_FALSE(IsAsciiWhiteSpace('a'));
    EXPECT_FALSE(IsAsciiWhiteSpace('1'));
    EXPECT_FALSE(IsAsciiWhiteSpace('+'));
    EXPECT_FALSE(IsAsciiWhiteSpace('_'));
}

TEST(IsAsciiWhiteSpaceTest, IsTrueForWhiteSpace)
{
    EXPECT_TRUE(IsAsciiWhiteSpace(' '));
    EXPECT_TRUE(IsAsciiWhiteSpace('\n'));
    EXPECT_TRUE(IsAsciiWhiteSpace('\r'));
    EXPECT_TRUE(IsAsciiWhiteSpace('\t'));
    EXPECT_TRUE(IsAsciiWhiteSpace('\v'));
    EXPECT_TRUE(IsAsciiWhiteSpace('\f'));
}

TEST(IsAsciiWordCharTest, IsFalseForNonWordChar)
{
    EXPECT_FALSE(IsAsciiWordChar('\0'));
    EXPECT_FALSE(IsAsciiWordChar('+'));
    EXPECT_FALSE(IsAsciiWordChar('.'));
    EXPECT_FALSE(IsAsciiWordChar(' '));
    EXPECT_FALSE(IsAsciiWordChar('\n'));
}

TEST(IsAsciiWordCharTest, IsTrueForLetter)
{
    EXPECT_TRUE(IsAsciiWordChar('a'));
    EXPECT_TRUE(IsAsciiWordChar('b'));
    EXPECT_TRUE(IsAsciiWordChar('A'));
    EXPECT_TRUE(IsAsciiWordChar('Z'));
}

TEST(IsAsciiWordCharTest, IsTrueForDigit)
{
    EXPECT_TRUE(IsAsciiWordChar('0'));
    EXPECT_TRUE(IsAsciiWordChar('1'));
    EXPECT_TRUE(IsAsciiWordChar('7'));
    EXPECT_TRUE(IsAsciiWordChar('9'));
}

TEST(IsAsciiWordCharTest, IsTrueForUnderscore)
{
    EXPECT_TRUE(IsAsciiWordChar('_'));
}

TEST(IsValidEscapeTest, IsFalseForNonPrintable)
{
    EXPECT_FALSE(IsValidEscape('\0'));
    EXPECT_FALSE(IsValidEscape('\007'));
}

TEST(IsValidEscapeTest, IsFalseForDigit)
{
    EXPECT_FALSE(IsValidEscape('0'));
    EXPECT_FALSE(IsValidEscape('9'));
}

TEST(IsValidEscapeTest, IsFalseForWhiteSpace)
{
    EXPECT_FALSE(IsValidEscape(' '));
    EXPECT_FALSE(IsValidEscape('\n'));
}

TEST(IsValidEscapeTest, IsFalseForSomeLetter)
{
    EXPECT_FALSE(IsValidEscape('a'));
    EXPECT_FALSE(IsValidEscape('Z'));
}

TEST(IsValidEscapeTest, IsTrueForPunct)
{
    EXPECT_TRUE(IsValidEscape('.'));
    EXPECT_TRUE(IsValidEscape('-'));
    EXPECT_TRUE(IsValidEscape('^'));
    EXPECT_TRUE(IsValidEscape('$'));
    EXPECT_TRUE(IsValidEscape('('));
    EXPECT_TRUE(IsValidEscape(']'));
    EXPECT_TRUE(IsValidEscape('{'));
    EXPECT_TRUE(IsValidEscape('|'));
}

TEST(IsValidEscapeTest, IsTrueForSomeLetter)
{
    EXPECT_TRUE(IsValidEscape('d'));
    EXPECT_TRUE(IsValidEscape('D'));
    EXPECT_TRUE(IsValidEscape('s'));
    EXPECT_TRUE(IsValidEscape('S'));
    EXPECT_TRUE(IsValidEscape('w'));
    EXPECT_TRUE(IsValidEscape('W'));
}

TEST(AtomMatchesCharTest, EscapedPunct)
{
    EXPECT_FALSE(AtomMatchesChar(true, '\\', '\0'));
    EXPECT_FALSE(AtomMatchesChar(true, '\\', ' '));
    EXPECT_FALSE(AtomMatchesChar(true, '_', '.'));
    EXPECT_FALSE(AtomMatchesChar(true, '.', 'a'));

    EXPECT_TRUE(AtomMatchesChar(true, '\\', '\\'));
    EXPECT_TRUE(AtomMatchesChar(true, '_', '_'));
    EXPECT_TRUE(AtomMatchesChar(true, '+', '+'));
    EXPECT_TRUE(AtomMatchesChar(true, '.', '.'));
}

TEST(AtomMatchesCharTest, Escaped_d)
{
    EXPECT_FALSE(AtomMatchesChar(true, 'd', '\0'));
    EXPECT_FALSE(AtomMatchesChar(true, 'd', 'a'));
    EXPECT_FALSE(AtomMatchesChar(true, 'd', '.'));

    EXPECT_TRUE(AtomMatchesChar(true, 'd', '0'));
    EXPECT_TRUE(AtomMatchesChar(true, 'd', '9'));
}

TEST(AtomMatchesCharTest, Escaped_D)
{
    EXPECT_FALSE(AtomMatchesChar(true, 'D', '0'));
    EXPECT_FALSE(AtomMatchesChar(true, 'D', '9'));

    EXPECT_TRUE(AtomMatchesChar(true, 'D', '\0'));
    EXPECT_TRUE(AtomMatchesChar(true, 'D', 'a'));
    EXPECT_TRUE(AtomMatchesChar(true, 'D', '-'));
}

TEST(AtomMatchesCharTest, Escaped_s)
{
    EXPECT_FALSE(AtomMatchesChar(true, 's', '\0'));
    EXPECT_FALSE(AtomMatchesChar(true, 's', 'a'));
    EXPECT_FALSE(AtomMatchesChar(true, 's', '.'));
    EXPECT_FALSE(AtomMatchesChar(true, 's', '9'));

    EXPECT_TRUE(AtomMatchesChar(true, 's', ' '));
    EXPECT_TRUE(AtomMatchesChar(true, 's', '\n'));
    EXPECT_TRUE(AtomMatchesChar(true, 's', '\t'));
}

TEST(AtomMatchesCharTest, Escaped_S)
{
    EXPECT_FALSE(AtomMatchesChar(true, 'S', ' '));
    EXPECT_FALSE(AtomMatchesChar(true, 'S', '\r'));

    EXPECT_TRUE(AtomMatchesChar(true, 'S', '\0'));
    EXPECT_TRUE(AtomMatchesChar(true, 'S', 'a'));
    EXPECT_TRUE(AtomMatchesChar(true, 'S', '9'));
}

TEST(AtomMatchesCharTest, Escaped_w)
{
    EXPECT_FALSE(AtomMatchesChar(true, 'w', '\0'));
    EXPECT_FALSE(AtomMatchesChar(true, 'w', '+'));
    EXPECT_FALSE(AtomMatchesChar(true, 'w', ' '));
    EXPECT_FALSE(AtomMatchesChar(true, 'w', '\n'));

    EXPECT_TRUE(AtomMatchesChar(true, 'w', '0'));
    EXPECT_TRUE(AtomMatchesChar(true, 'w', 'b'));
    EXPECT_TRUE(AtomMatchesChar(true, 'w', 'C'));
    EXPECT_TRUE(AtomMatchesChar(true, 'w', '_'));
}

TEST(AtomMatchesCharTest, Escaped_W)
{
    EXPECT_FALSE(AtomMatchesChar(true, 'W', 'A'));
    EXPECT_FALSE(AtomMatchesChar(true, 'W', 'b'));
    EXPECT_FALSE(AtomMatchesChar(true, 'W', '9'));
    EXPECT_FALSE(AtomMatchesChar(true, 'W', '_'));

    EXPECT_TRUE(AtomMatchesChar(true, 'W', '\0'));
    EXPECT_TRUE(AtomMatchesChar(true, 'W', '*'));
    EXPECT_TRUE(AtomMatchesChar(true, 'W', '\n'));
}

TEST(AtomMatchesCharTest, EscapedWhiteSpace)
{
    EXPECT_FALSE(AtomMatchesChar(true, 'f', '\0'));
    EXPECT_FALSE(AtomMatchesChar(true, 'f', '\n'));
    EXPECT_FALSE(AtomMatchesChar(true, 'n', '\0'));
    EXPECT_FALSE(AtomMatchesChar(true, 'n', '\r'));
    EXPECT_FALSE(AtomMatchesChar(true, 'r', '\0'));
    EXPECT_FALSE(AtomMatchesChar(true, 'r', 'a'));
    EXPECT_FALSE(AtomMatchesChar(true, 't', '\0'));
    EXPECT_FALSE(AtomMatchesChar(true, 't', 't'));
    EXPECT_FALSE(AtomMatchesChar(true, 'v', '\0'));
    EXPECT_FALSE(AtomMatchesChar(true, 'v', '\f'));

    EXPECT_TRUE(AtomMatchesChar(true, 'f', '\f'));
    EXPECT_TRUE(AtomMatchesChar(true, 'n', '\n'));
    EXPECT_TRUE(AtomMatchesChar(true, 'r', '\r'));
    EXPECT_TRUE(AtomMatchesChar(true, 't', '\t'));
    EXPECT_TRUE(AtomMatchesChar(true, 'v', '\v'));
}

TEST(AtomMatchesCharTest, UnescapedDot)
{
    EXPECT_FALSE(AtomMatchesChar(false, '.', '\n'));

    EXPECT_TRUE(AtomMatchesChar(false, '.', '\0'));
    EXPECT_TRUE(AtomMatchesChar(false, '.', '.'));
    EXPECT_TRUE(AtomMatchesChar(false, '.', 'a'));
    EXPECT_TRUE(AtomMatchesChar(false, '.', ' '));
}

TEST(AtomMatchesCharTest, UnescapedChar)
{
    EXPECT_FALSE(AtomMatchesChar(false, 'a', '\0'));
    EXPECT_FALSE(AtomMatchesChar(false, 'a', 'b'));
    EXPECT_FALSE(AtomMatchesChar(false, '$', 'a'));

    EXPECT_TRUE(AtomMatchesChar(false, '$', '$'));
    EXPECT_TRUE(AtomMatchesChar(false, '5', '5'));
    EXPECT_TRUE(AtomMatchesChar(false, 'Z', 'Z'));
}

TEST(ValidateRegexTest, GeneratesFailureAndReturnsFalseForInvalid)
{
    EXPECT_NONFATAL_FAILURE(ASSERT_FALSE(ValidateRegex(NULL)),
                            "NULL is not a valid simple regular expression");
    EXPECT_NONFATAL_FAILURE(
        ASSERT_FALSE(ValidateRegex("a\\")),
        "Syntax error at index 1 in simple regular expression \"a\\\": ");
    EXPECT_NONFATAL_FAILURE(ASSERT_FALSE(ValidateRegex("a\\")),
                            "'\\' cannot appear at the end");
    EXPECT_NONFATAL_FAILURE(ASSERT_FALSE(ValidateRegex("\\n\\")),
                            "'\\' cannot appear at the end");
    EXPECT_NONFATAL_FAILURE(ASSERT_FALSE(ValidateRegex("\\s\\hb")),
                            "invalid escape sequence \"\\h\"");
    EXPECT_NONFATAL_FAILURE(ASSERT_FALSE(ValidateRegex("^^")),
                            "'^' can only appear at the beginning");
    EXPECT_NONFATAL_FAILURE(ASSERT_FALSE(ValidateRegex(".*^b")),
                            "'^' can only appear at the beginning");
    EXPECT_NONFATAL_FAILURE(ASSERT_FALSE(ValidateRegex("$$")),
                            "'$' can only appear at the end");
    EXPECT_NONFATAL_FAILURE(ASSERT_FALSE(ValidateRegex("^$a")),
                            "'$' can only appear at the end");
    EXPECT_NONFATAL_FAILURE(ASSERT_FALSE(ValidateRegex("a(b")),
                            "'(' is unsupported");
    EXPECT_NONFATAL_FAILURE(ASSERT_FALSE(ValidateRegex("ab)")),
                            "')' is unsupported");
    EXPECT_NONFATAL_FAILURE(ASSERT_FALSE(ValidateRegex("[ab")),
                            "'[' is unsupported");
    EXPECT_NONFATAL_FAILURE(ASSERT_FALSE(ValidateRegex("a{2")),
                            "'{' is unsupported");
    EXPECT_NONFATAL_FAILURE(ASSERT_FALSE(ValidateRegex("?")),
                            "'?' can only follow a repeatable token");
    EXPECT_NONFATAL_FAILURE(ASSERT_FALSE(ValidateRegex("^*")),
                            "'*' can only follow a repeatable token");
    EXPECT_NONFATAL_FAILURE(ASSERT_FALSE(ValidateRegex("5*+")),
                            "'+' can only follow a repeatable token");
}

TEST(ValidateRegexTest, ReturnsTrueForValid)
{
    EXPECT_TRUE(ValidateRegex(""));
    EXPECT_TRUE(ValidateRegex("a"));
    EXPECT_TRUE(ValidateRegex(".*"));
    EXPECT_TRUE(ValidateRegex("^a_+"));
    EXPECT_TRUE(ValidateRegex("^a\\t\\&?"));
    EXPECT_TRUE(ValidateRegex("09*$"));
    EXPECT_TRUE(ValidateRegex("^Z$"));
    EXPECT_TRUE(ValidateRegex("a\\^Z\\$\\(\\)\\|\\[\\]\\{\\}"));
}

TEST(MatchRepetitionAndRegexAtHeadTest, WorksForZeroOrOne)
{
    EXPECT_FALSE(MatchRepetitionAndRegexAtHead(false, 'a', '?', "a", "ba"));
    // Repeating more than once.
    EXPECT_FALSE(MatchRepetitionAndRegexAtHead(false, 'a', '?', "b", "aab"));

    // Repeating zero times.
    EXPECT_TRUE(MatchRepetitionAndRegexAtHead(false, 'a', '?', "b", "ba"));
    // Repeating once.
    EXPECT_TRUE(MatchRepetitionAndRegexAtHead(false, 'a', '?', "b", "ab"));
    EXPECT_TRUE(MatchRepetitionAndRegexAtHead(false, '#', '?', ".", "##"));
}

TEST(MatchRepetitionAndRegexAtHeadTest, WorksForZeroOrMany)
{
    EXPECT_FALSE(MatchRepetitionAndRegexAtHead(false, '.', '*', "a$", "baab"));

    // Repeating zero times.
    EXPECT_TRUE(MatchRepetitionAndRegexAtHead(false, '.', '*', "b", "bc"));
    // Repeating once.
    EXPECT_TRUE(MatchRepetitionAndRegexAtHead(false, '.', '*', "b", "abc"));
    // Repeating more than once.
    EXPECT_TRUE(MatchRepetitionAndRegexAtHead(true, 'w', '*', "-", "ab_1-g"));
}

TEST(MatchRepetitionAndRegexAtHeadTest, WorksForOneOrMany)
{
    EXPECT_FALSE(MatchRepetitionAndRegexAtHead(false, '.', '+', "a$", "baab"));
    // Repeating zero times.
    EXPECT_FALSE(MatchRepetitionAndRegexAtHead(false, '.', '+', "b", "bc"));

    // Repeating once.
    EXPECT_TRUE(MatchRepetitionAndRegexAtHead(false, '.', '+', "b", "abc"));
    // Repeating more than once.
    EXPECT_TRUE(MatchRepetitionAndRegexAtHead(true, 'w', '+', "-", "ab_1-g"));
}

TEST(MatchRegexAtHeadTest, ReturnsTrueForEmptyRegex)
{
    EXPECT_TRUE(MatchRegexAtHead("", ""));
    EXPECT_TRUE(MatchRegexAtHead("", "ab"));
}

TEST(MatchRegexAtHeadTest, WorksWhenDollarIsInRegex)
{
    EXPECT_FALSE(MatchRegexAtHead("$", "a"));

    EXPECT_TRUE(MatchRegexAtHead("$", ""));
    EXPECT_TRUE(MatchRegexAtHead("a$", "a"));
}

TEST(MatchRegexAtHeadTest, WorksWhenRegexStartsWithEscapeSequence)
{
    EXPECT_FALSE(MatchRegexAtHead("\\w", "+"));
    EXPECT_FALSE(MatchRegexAtHead("\\W", "ab"));

    EXPECT_TRUE(MatchRegexAtHead("\\sa", "\nab"));
    EXPECT_TRUE(MatchRegexAtHead("\\d", "1a"));
}

TEST(MatchRegexAtHeadTest, WorksWhenRegexStartsWithRepetition)
{
    EXPECT_FALSE(MatchRegexAtHead(".+a", "abc"));
    EXPECT_FALSE(MatchRegexAtHead("a?b", "aab"));

    EXPECT_TRUE(MatchRegexAtHead(".*a", "bc12-ab"));
    EXPECT_TRUE(MatchRegexAtHead("a?b", "b"));
    EXPECT_TRUE(MatchRegexAtHead("a?b", "ab"));
}

TEST(MatchRegexAtHeadTest,
     WorksWhenRegexStartsWithRepetionOfEscapeSequence)
{
    EXPECT_FALSE(MatchRegexAtHead("\\.+a", "abc"));
    EXPECT_FALSE(MatchRegexAtHead("\\s?b", "  b"));

    EXPECT_TRUE(MatchRegexAtHead("\\(*a", "((((ab"));
    EXPECT_TRUE(MatchRegexAtHead("\\^?b", "^b"));
    EXPECT_TRUE(MatchRegexAtHead("\\\\?b", "b"));
    EXPECT_TRUE(MatchRegexAtHead("\\\\?b", "\\b"));
}

TEST(MatchRegexAtHeadTest, MatchesSequentially)
{
    EXPECT_FALSE(MatchRegexAtHead("ab.*c", "acabc"));

    EXPECT_TRUE(MatchRegexAtHead("ab.*c", "ab-fsc"));
}

TEST(MatchRegexAnywhereTest, ReturnsFalseWhenStringIsNull)
{
    EXPECT_FALSE(MatchRegexAnywhere("", NULL));
}

TEST(MatchRegexAnywhereTest, WorksWhenRegexStartsWithCaret)
{
    EXPECT_FALSE(MatchRegexAnywhere("^a", "ba"));
    EXPECT_FALSE(MatchRegexAnywhere("^$", "a"));

    EXPECT_TRUE(MatchRegexAnywhere("^a", "ab"));
    EXPECT_TRUE(MatchRegexAnywhere("^", "ab"));
    EXPECT_TRUE(MatchRegexAnywhere("^$", ""));
}

TEST(MatchRegexAnywhereTest, ReturnsFalseWhenNoMatch)
{
    EXPECT_FALSE(MatchRegexAnywhere("a", "bcde123"));
    EXPECT_FALSE(MatchRegexAnywhere("a.+a", "--aa88888888"));
}

TEST(MatchRegexAnywhereTest, ReturnsTrueWhenMatchingPrefix)
{
    EXPECT_TRUE(MatchRegexAnywhere("\\w+", "ab1_ - 5"));
    EXPECT_TRUE(MatchRegexAnywhere(".*=", "="));
    EXPECT_TRUE(MatchRegexAnywhere("x.*ab?.*bc", "xaaabc"));
}

TEST(MatchRegexAnywhereTest, ReturnsTrueWhenMatchingNonPrefix)
{
    EXPECT_TRUE(MatchRegexAnywhere("\\w+", "$$$ ab1_ - 5"));
    EXPECT_TRUE(MatchRegexAnywhere("\\.+=", "=  ...="));
}

// Tests RE's implicit constructors.
TEST(RETest, ImplicitConstructorWorks)
{
    const RE empty("");
    EXPECT_STREQ("", empty.pattern());

    const RE simple("hello");
    EXPECT_STREQ("hello", simple.pattern());
}

// Tests that RE's constructors reject invalid regular expressions.
TEST(RETest, RejectsInvalidRegex)
{
    EXPECT_NONFATAL_FAILURE({
        const RE normal(NULL);
    },
                            "NULL is not a valid simple regular expression");

    EXPECT_NONFATAL_FAILURE({
        const RE normal(".*(\\w+");
    },
                            "'(' is unsupported");

    EXPECT_NONFATAL_FAILURE({
        const RE invalid("^?");
    },
                            "'?' can only follow a repeatable token");
}

// Tests RE::FullMatch().
TEST(RETest, FullMatchWorks)
{
    const RE empty("");
    EXPECT_TRUE(RE::FullMatch("", empty));
    EXPECT_FALSE(RE::FullMatch("a", empty));

    const RE re1("a");
    EXPECT_TRUE(RE::FullMatch("a", re1));

    const RE re("a.*z");
    EXPECT_TRUE(RE::FullMatch("az", re));
    EXPECT_TRUE(RE::FullMatch("axyz", re));
    EXPECT_FALSE(RE::FullMatch("baz", re));
    EXPECT_FALSE(RE::FullMatch("azy", re));
}

// Tests RE::PartialMatch().
TEST(RETest, PartialMatchWorks)
{
    const RE empty("");
    EXPECT_TRUE(RE::PartialMatch("", empty));
    EXPECT_TRUE(RE::PartialMatch("a", empty));

    const RE re("a.*z");
    EXPECT_TRUE(RE::PartialMatch("az", re));
    EXPECT_TRUE(RE::PartialMatch("axyz", re));
    EXPECT_TRUE(RE::PartialMatch("baz", re));
    EXPECT_TRUE(RE::PartialMatch("azy", re));
    EXPECT_FALSE(RE::PartialMatch("zza", re));
}

#endif // GTEST_USES_POSIX_RE

#if !GTEST_OS_WINDOWS_MOBILE

TEST(CaptureTest, CapturesStdout)
{
    CaptureStdout();
    fprintf(stdout, "abc");
    EXPECT_STREQ("abc", GetCapturedStdout().c_str());

    CaptureStdout();
    fprintf(stdout, "def%cghi", '\0');
    EXPECT_EQ(::std::string("def\0ghi", 7), ::std::string(GetCapturedStdout()));
}

TEST(CaptureTest, CapturesStderr)
{
    CaptureStderr();
    fprintf(stderr, "jkl");
    EXPECT_STREQ("jkl", GetCapturedStderr().c_str());

    CaptureStderr();
    fprintf(stderr, "jkl%cmno", '\0');
    EXPECT_EQ(::std::string("jkl\0mno", 7), ::std::string(GetCapturedStderr()));
}

// Tests that stdout and stderr capture don't interfere with each other.
TEST(CaptureTest, CapturesStdoutAndStderr)
{
    CaptureStdout();
    CaptureStderr();
    fprintf(stdout, "pqr");
    fprintf(stderr, "stu");
    EXPECT_STREQ("pqr", GetCapturedStdout().c_str());
    EXPECT_STREQ("stu", GetCapturedStderr().c_str());
}

TEST(CaptureDeathTest, CannotReenterStdoutCapture)
{
    CaptureStdout();
    EXPECT_DEATH_IF_SUPPORTED(CaptureStdout(),
                              "Only one stdout capturer can exist at a time");
    GetCapturedStdout();

    // We cannot test stderr capturing using death tests as they use it
    // themselves.
}

#endif // !GTEST_OS_WINDOWS_MOBILE

TEST(ThreadLocalTest, DefaultConstructorInitializesToDefaultValues)
{
    ThreadLocal<int> t1;
    EXPECT_EQ(0, t1.get());

    ThreadLocal<void *> t2;
    EXPECT_TRUE(t2.get() == NULL);
}

TEST(ThreadLocalTest, SingleParamConstructorInitializesToParam)
{
    ThreadLocal<int> t1(123);
    EXPECT_EQ(123, t1.get());

    int i = 0;
    ThreadLocal<int *> t2(&i);
    EXPECT_EQ(&i, t2.get());
}

class NoDefaultContructor
{
public:
    explicit NoDefaultContructor(const char *) {}
    NoDefaultContructor(const NoDefaultContructor &) {}
};

TEST(ThreadLocalTest, ValueDefaultContructorIsNotRequiredForParamVersion)
{
    ThreadLocal<NoDefaultContructor> bar(NoDefaultContructor("foo"));
    bar.pointer();
}

TEST(ThreadLocalTest, GetAndPointerReturnSameValue)
{
    ThreadLocal<std::string> thread_local_string;

    EXPECT_EQ(thread_local_string.pointer(), &(thread_local_string.get()));

    // Verifies the condition still holds after calling set.
    thread_local_string.set("foo");
    EXPECT_EQ(thread_local_string.pointer(), &(thread_local_string.get()));
}

TEST(ThreadLocalTest, PointerAndConstPointerReturnSameValue)
{
    ThreadLocal<std::string> thread_local_string;
    const ThreadLocal<std::string> &const_thread_local_string =
        thread_local_string;

    EXPECT_EQ(thread_local_string.pointer(), const_thread_local_string.pointer());

    thread_local_string.set("foo");
    EXPECT_EQ(thread_local_string.pointer(), const_thread_local_string.pointer());
}

#if GTEST_IS_THREADSAFE

void AddTwo(int *param)
{
    *param += 2;
}

TEST(ThreadWithParamTest, ConstructorExecutesThreadFunc)
{
    int i = 40;
    ThreadWithParam<int *> thread(&AddTwo, &i, NULL);
    thread.Join();
    EXPECT_EQ(42, i);
}

TEST(MutexDeathTest, AssertHeldShouldAssertWhenNotLocked)
{
    // AssertHeld() is flaky only in the presence of multiple threads accessing
    // the lock. In this case, the test is robust.
    EXPECT_DEATH_IF_SUPPORTED({
        Mutex m;
        {
            MutexLock lock(&m);
        }
        m.AssertHeld();
    },
                              "thread .*hold");
}

TEST(MutexTest, AssertHeldShouldNotAssertWhenLocked)
{
    Mutex m;
    MutexLock lock(&m);
    m.AssertHeld();
}

class AtomicCounterWithMutex
{
public:
    explicit AtomicCounterWithMutex(Mutex *mutex)
        : value_(0)
        , mutex_(mutex)
        , random_(42)
    {
    }

    void Increment()
    {
        MutexLock lock(mutex_);
        int temp = value_;
        {
            // We need to put up a memory barrier to prevent reads and writes to
            // value_ rearranged with the call to SleepMilliseconds when observed
            // from other threads.
#if GTEST_HAS_PTHREAD
            // On POSIX, locking a mutex puts up a memory barrier.  We cannot use
            // Mutex and MutexLock here or rely on their memory barrier
            // functionality as we are testing them here.
            pthread_mutex_t memory_barrier_mutex;
            GTEST_CHECK_POSIX_SUCCESS_(
                pthread_mutex_init(&memory_barrier_mutex, NULL));
            GTEST_CHECK_POSIX_SUCCESS_(pthread_mutex_lock(&memory_barrier_mutex));

            SleepMilliseconds(random_.Generate(30));

            GTEST_CHECK_POSIX_SUCCESS_(pthread_mutex_unlock(&memory_barrier_mutex));
            GTEST_CHECK_POSIX_SUCCESS_(pthread_mutex_destroy(&memory_barrier_mutex));
#elif GTEST_OS_WINDOWS
            // On Windows, performing an interlocked access puts up a memory barrier.
            volatile LONG dummy = 0;
            ::InterlockedIncrement(&dummy);
            SleepMilliseconds(random_.Generate(30));
            ::InterlockedIncrement(&dummy);
#else
#error "Memory barrier not implemented on this platform."
#endif // GTEST_HAS_PTHREAD
        }
        value_ = temp + 1;
    }
    int value() const { return value_; }

private:
    volatile int value_;
    Mutex *const mutex_; // Protects value_.
    Random random_;
};

void CountingThreadFunc(pair<AtomicCounterWithMutex *, int> param)
{
    for (int i = 0; i < param.second; ++i)
        param.first->Increment();
}

// Tests that the mutex only lets one thread at a time to lock it.
TEST(MutexTest, OnlyOneThreadCanLockAtATime)
{
    Mutex mutex;
    AtomicCounterWithMutex locked_counter(&mutex);

    typedef ThreadWithParam<pair<AtomicCounterWithMutex *, int>> ThreadType;
    const int kCycleCount = 20;
    const int kThreadCount = 7;
    scoped_ptr<ThreadType> counting_threads[kThreadCount];
    Notification threads_can_start;
    // Creates and runs kThreadCount threads that increment locked_counter
    // kCycleCount times each.
    for (int i = 0; i < kThreadCount; ++i) {
        counting_threads[i].reset(new ThreadType(&CountingThreadFunc,
                                                 make_pair(&locked_counter,
                                                           kCycleCount),
                                                 &threads_can_start));
    }
    threads_can_start.Notify();
    for (int i = 0; i < kThreadCount; ++i)
        counting_threads[i]->Join();

    // If the mutex lets more than one thread to increment the counter at a
    // time, they are likely to encounter a race condition and have some
    // increments overwritten, resulting in the lower then expected counter
    // value.
    EXPECT_EQ(kCycleCount * kThreadCount, locked_counter.value());
}

template<typename T>
void RunFromThread(void(func)(T), T param)
{
    ThreadWithParam<T> thread(func, param, NULL);
    thread.Join();
}

void RetrieveThreadLocalValue(
    pair<ThreadLocal<std::string> *, std::string *> param)
{
    *param.second = param.first->get();
}

TEST(ThreadLocalTest, ParameterizedConstructorSetsDefault)
{
    ThreadLocal<std::string> thread_local_string("foo");
    EXPECT_STREQ("foo", thread_local_string.get().c_str());

    thread_local_string.set("bar");
    EXPECT_STREQ("bar", thread_local_string.get().c_str());

    std::string result;
    RunFromThread(&RetrieveThreadLocalValue,
                  make_pair(&thread_local_string, &result));
    EXPECT_STREQ("foo", result.c_str());
}

// Keeps track of whether of destructors being called on instances of
// DestructorTracker.  On Windows, waits for the destructor call reports.
class DestructorCall
{
public:
    DestructorCall()
    {
        invoked_ = false;
#if GTEST_OS_WINDOWS
        wait_event_.Reset(::CreateEvent(NULL, TRUE, FALSE, NULL));
        GTEST_CHECK_(wait_event_.Get() != NULL);
#endif
    }

    bool CheckDestroyed() const
    {
#if GTEST_OS_WINDOWS
        if (::WaitForSingleObject(wait_event_.Get(), 1000) != WAIT_OBJECT_0)
            return false;
#endif
        return invoked_;
    }

    void ReportDestroyed()
    {
        invoked_ = true;
#if GTEST_OS_WINDOWS
        ::SetEvent(wait_event_.Get());
#endif
    }

    static std::vector<DestructorCall *> &List() { return *list_; }

    static void ResetList()
    {
        for (size_t i = 0; i < list_->size(); ++i) {
            delete list_->at(i);
        }
        list_->clear();
    }

private:
    bool invoked_;
#if GTEST_OS_WINDOWS
    AutoHandle wait_event_;
#endif
    static std::vector<DestructorCall *> *const list_;

    GTEST_DISALLOW_COPY_AND_ASSIGN_(DestructorCall);
};

std::vector<DestructorCall *> *const DestructorCall::list_ =
    new std::vector<DestructorCall *>;

// DestructorTracker keeps track of whether its instances have been
// destroyed.
class DestructorTracker
{
public:
    DestructorTracker()
        : index_(GetNewIndex())
    {
    }
    DestructorTracker(const DestructorTracker & /* rhs */)
        : index_(GetNewIndex())
    {
    }
    ~DestructorTracker()
    {
        // We never access DestructorCall::List() concurrently, so we don't need
        // to protect this access with a mutex.
        DestructorCall::List()[index_]->ReportDestroyed();
    }

private:
    static size_t GetNewIndex()
    {
        DestructorCall::List().push_back(new DestructorCall);
        return DestructorCall::List().size() - 1;
    }
    const size_t index_;

    GTEST_DISALLOW_ASSIGN_(DestructorTracker);
};

typedef ThreadLocal<DestructorTracker> *ThreadParam;

void CallThreadLocalGet(ThreadParam thread_local_param)
{
    thread_local_param->get();
}

// Tests that when a ThreadLocal object dies in a thread, it destroys
// the managed object for that thread.
TEST(ThreadLocalTest, DestroysManagedObjectForOwnThreadWhenDying)
{
    DestructorCall::ResetList();

    {
        ThreadLocal<DestructorTracker> thread_local_tracker;
        ASSERT_EQ(0U, DestructorCall::List().size());

        // This creates another DestructorTracker object for the main thread.
        thread_local_tracker.get();
        ASSERT_EQ(1U, DestructorCall::List().size());
        ASSERT_FALSE(DestructorCall::List()[0]->CheckDestroyed());
    }

    // Now thread_local_tracker has died.
    ASSERT_EQ(1U, DestructorCall::List().size());
    EXPECT_TRUE(DestructorCall::List()[0]->CheckDestroyed());

    DestructorCall::ResetList();
}

// Tests that when a thread exits, the thread-local object for that
// thread is destroyed.
TEST(ThreadLocalTest, DestroysManagedObjectAtThreadExit)
{
    DestructorCall::ResetList();

    {
        ThreadLocal<DestructorTracker> thread_local_tracker;
        ASSERT_EQ(0U, DestructorCall::List().size());

        // This creates another DestructorTracker object in the new thread.
        ThreadWithParam<ThreadParam> thread(
            &CallThreadLocalGet, &thread_local_tracker, NULL);
        thread.Join();

        // The thread has exited, and we should have a DestroyedTracker
        // instance created for it. But it may not have been destroyed yet.
        ASSERT_EQ(1U, DestructorCall::List().size());
    }

    // The thread has exited and thread_local_tracker has died.
    ASSERT_EQ(1U, DestructorCall::List().size());
    EXPECT_TRUE(DestructorCall::List()[0]->CheckDestroyed());

    DestructorCall::ResetList();
}

TEST(ThreadLocalTest, ThreadLocalMutationsAffectOnlyCurrentThread)
{
    ThreadLocal<std::string> thread_local_string;
    thread_local_string.set("Foo");
    EXPECT_STREQ("Foo", thread_local_string.get().c_str());

    std::string result;
    RunFromThread(&RetrieveThreadLocalValue,
                  make_pair(&thread_local_string, &result));
    EXPECT_TRUE(result.empty());
}

#endif // GTEST_IS_THREADSAFE

#if GTEST_OS_WINDOWS
TEST(WindowsTypesTest, HANDLEIsVoidStar)
{
    StaticAssertTypeEq<HANDLE, void *>();
}

#if GTEST_OS_WINDOWS_MINGW && !defined(__MINGW64_VERSION_MAJOR)
TEST(WindowsTypesTest, _CRITICAL_SECTIONIs_CRITICAL_SECTION)
{
    StaticAssertTypeEq<CRITICAL_SECTION, _CRITICAL_SECTION>();
}
#else
TEST(WindowsTypesTest, CRITICAL_SECTIONIs_RTL_CRITICAL_SECTION)
{
    StaticAssertTypeEq<CRITICAL_SECTION, _RTL_CRITICAL_SECTION>();
}
#endif

#endif // GTEST_OS_WINDOWS

} // namespace internal
} // namespace testing
